Effect of Cu\(^{2+}\) Dopant on the Formation of Zinc Oxide Microrod Fabricated by a Hydrothermal Method

S. Nguyen, Phuoc Sang Le, T. Luu
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引用次数: 0

Abstract

Reconstruction and stabilization of polar oxide surfaces, such as ZnO, contribute a significant role in photocatalysis, chemical sensing, and optoelectronic applications, however their physical chemistry insight is still a puzzle in the surface science. In this work, the  polar surface instability induced the morphological evolution of hydrothermally synthesized micro-rod ZnO doped with various contents of Cu2+ ion (1-10 at.%)  was investigated. The transformation of micro-rod morphology from the high aspect ratio flower-like shape of the pure ZnO to the hexagonal prism-like shape of the doped ZnO was characterized by X-ray diffractometry, scanning electron microscopy and micro Raman spectroscopy. The chemically active Zn-terminated polar surface in doped samples was less positive charge density which was the main reason to cancel the electrostatic instability for the dominant  growing direction. Furthermore, the schematic models of the electron transferring from the conduction band region to the electron trap centre of Cu2+, and the Zn-terminated polar surface reconstruction were proposed for the morphological evolution mechanism.
Cu \(^{2+}\)掺杂剂对水热法制备氧化锌微棒形成的影响
极性氧化物表面(如ZnO)的重建和稳定在光催化、化学传感和光电子应用中发挥着重要作用,但其物理化学性质仍然是表面科学中的一个难题。本文研究了掺杂不同Cu2+离子(1-10 at.%)的水热合成微棒ZnO的极性表面不稳定性对其形貌演变的影响。利用x射线衍射仪、扫描电镜和微拉曼光谱对纯ZnO的高纵横比花状形貌向掺杂ZnO的六角形棱柱状形貌转变进行了表征。掺杂样品中具有化学活性的锌端极性表面正电荷密度较小,这是抵消静电不稳定性的主要原因。此外,还提出了电子从Cu2+的导带区向电子阱中心转移的示意图模型和zn端极性表面重构的模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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